KR101802502B1 - Apparatus for watching fault of power distribution line - Google Patents

Abstract

The present invention relates to an apparatus for monitoring a fault section line of a power distribution line, which comprises: a fault monitoring means; a fault display means; and a bypass means, wherein whether fault occurs in a unit distribution line and a jump line between telephone poles is sensed and a fault signal is transmitted to a management center of a power company for monitoring; fault status including information on fault section and information on power outage recovery schedule is displayed on a telephone pole, thereby enabling a field patrol to identify the fault situation at one glance and allowing an energy customer living nearby to an area of power outage to recognize the cause of power outage and take actions against the power outage so that convenience of a life can be given; even though a fault occurs in a system which transmits a fault signal to make transmission of a fault signal impossible, a patrol of a power company or an energy customer nearby reports the fault situation to the management center, thereby letting the management center rapidly take actions against the fault; and if a fault occurs in each unit distribution line, unit distribution lines disposed at both sides of the corresponding unit distribution line are directly connected, thereby letting an energy customer connected to the other unit distribution lines except for the energy customer connected to the unit distribution line where a fault occurs avoid power outage to minimize the range of power outage.

Description

[0001] The present invention relates to a monitoring apparatus for monitoring a fault in a distribution line,

More particularly, the present invention detects a failure of a unit distribution line and a jump line between a pole and a pole and sends a failure signal to a management center of a power company In addition to displaying the fault situation including the fault section information and the information on the scheduled date of power failure recovery on the electric pole, the patrol officer can confirm the fault situation at the spot by observing the fault situation. It is possible to cope with a power failure, thereby making it possible to provide convenience of living, and even when a fault occurs in a system for transmitting a fault signal and a fault signal is not transmitted, To the management center so that the management center can quickly respond to the breakdown, In the event of a fault in a faulted line, the unit distribution line located on both sides of the unit distribution line is directly connected so as to minimize the power outage by eliminating power outage for the customer connected to the unit distribution line except for the customer connected to the faulty distribution line. And more particularly, to a fault line monitoring apparatus for a distribution line.

Generally, the power generated by a power plant is transmitted through a special high-pressure power distribution line that is insulated and supported by a power transmission tower by boosting (345kV or higher ultrahigh pressure or above 765kV ultra high voltage) at a substation installed adjacent to a power plant. (22,9 kV class high pressure) in the final substation and distributed to the large-scale customer area through the processing distribution line insulated and supported in the mains pole. Finally, the commercial voltage that can be used in the customer by the pole- 230V, 380V) to be distributed to the customer through processing distribution lines or underground distribution lines.

A power distribution line includes a pole disposed at a predetermined interval, a crowbar fixed to the pole, a unit distribution line supported in an insulated state through a suspension insulator, a jump line connecting the unit distribution lines, And each of the unit distribution lines is connected to each of the customers through a lead line formed of a working wire or an underground wire.

Such a distribution line is exposed to wind and rain, and may cause a failure due to various factors. Such failure leads to a power failure to the customer.

At this time, if any one of the plurality of unit power distribution lines constituting the power distribution line is broken and the current does not flow, the current does not flow in the entire power distribution line including the remaining unit distribution line connected by the jump line, A power failure occurs in all the cafeteria connected to the lead line.

Conventionally, as a prior art for monitoring the failure of such a distribution line, Korean Utility Model Publication No. 10-2011-0022904 (Published Mar. 23, 2011) "Distribution Line Failure Monitoring System" (hereinafter referred to as "Prior Art 1" A fault detection server that receives a fault detection from the detector and generates a control signal based on a position on the power distribution line of the detector, and a fault detection server that detects a fault in the plurality Discloses a technique for quickly detecting a failure occurring in a distribution line and blocking a fault occurrence point from the distribution line to efficiently operate the distribution line.

(Hereinafter referred to as "Prior Art 2") and Korean Patent No. 10-1514020 (Registered on June 23, 2011, Registered on Mar. 23, 2011) (Hereinafter referred to as "prior art 3") discloses a technique for remotely monitoring and checking faults.

(Hereinafter referred to as " Prior Art 4 ") of the Korean Registered Patent No. 10-1626141 (registered on May 25, 2015) as a prior art is a processing power transmission line, a first cut- When a failure occurs in one or more of the second reduction line and the processing distribution line, the fault number monitoring means and the fault number data are sent to the remote monitoring server so as to take measures, and at the same time, To fourth lamps and to keep the ramp plate tilted toward the ground so that the on-site patrols and the customers can see the fault, and in particular, the overhead power line, the first cut line, the second cut line, It is possible to confirm which part of the processing power distribution line is faulty so that it can take prompt and appropriate action and the field patrol can confirm the fault situation at the sight at the spot, In case of a nearby power outage, the cause of the power outage can be recognized, so that it is possible to cope with a power outage, thereby making it possible to provide a living convenience, and even when a fault occurs in a system for transmitting a fault signal, Of the patrols or the surrounding residents are reported to the management center so that the management center can quickly respond to the failure.

However, the above-mentioned prior arts are only for monitoring the failure of the distribution line to identify the fault section, and then allowing the operator to respond to the site and cope with it, and a failure occurs in any one of the plurality of unit distribution lines constituting the distribution line, The current does not flow through the distribution line including the remaining unit distribution lines connected by the jump line, so that the conventional problem of power failure occurring in all the customers connected to the unit distribution line through the distribution line by the lead line can not be solved.

Therefore, it is required to develop a technique for minimizing the power failure period by preventing the power failure in a section other than the fault section, even if the failure section can not prevent the power failure.

Korean Patent Publication No. 10-2011-0022904 (Published on March 23, 2011) "Distribution Line Failure Monitoring System" Korean Registered Patent No. 10-1040732 (Registered on Mar. 23, 2011) "Surveillance device for transmission and distribution lines" Korean Registered Patent No. 10-1514020 (Registered on April 15, 2015) "Power Loss Monitoring and Saving Device for Processing Distribution Line" Korean Registered Patent No. 10-1626141 (Registered on May 25, 2015) "Fault Monitoring Device for Processed Distribution Line"

Accordingly, it is an object of the present invention to provide a power supply system capable of detecting a failure of a unit distribution line and a jump line between a pole and a pole and sending out a failure signal to a management center of a power company to monitor the failure, The on-site patrol can confirm the fault situation at a sight in the field, and the cause of the power failure can be recognized as the out-of-place nearby customer, so that it is possible to cope with the power failure, Even if the fault signal is not transmitted due to a fault in the system that sends out the signal, the patrol of the power company or the nearby customer can report the fault situation to the control center so that the control center can quickly respond to the fault In addition, if a failure occurs in each unit distribution line, the unit distribution located on both sides of the corresponding unit distribution line By a direct connection intended to provide a fault section of the line monitoring apparatus to a distribution line that in order to minimize the electrostatic range to eliminate the electrostatic voltage distribution line for suyongga connected to the remaining units other than the units connected to the distribution line suyongga fault occurred.

According to an aspect of the present invention, there is provided a method of controlling an electric power transmission line, including a plurality of unit distribution lines supported in an insulated state via a suspending insulator and a jump line connecting the unit distribution lines, A line monitoring apparatus comprising: a sensing sensor unit including a power line sensor installed on a unit distribution line and a jump line sensor installed on the jump line; and a controller for storing a prime number and fault data, A monitoring control unit for outputting a storing instruction and a sending instruction of the telephone number and the fault data to the memory unit according to the detection signal of the detection sensor unit; and a control unit for transmitting the telephone number and the fault data to the remote monitoring server And a communication unit for transmitting the signal to the control unit; A motor mounted vertically on the upper end of the mount and having a motor shaft facing downward, left and right sliders slidable in the left and right directions and overlapped with each other in the front and rear direction, A left rack coupled to the right slider and engaged with the pinion at the rear, and a right rack coupled to the right slider and a left rack coupled to the pinion at the rear, A left liquid crystal panel attached to the front surface of the slider, and a right liquid crystal panel attached to the front surface of the right slider; A memory section in which fault data and failure recovery time data for each fault section are stored; a motor control command for the motor and a fault section display control for the left and right liquid crystal panels according to a detection signal of the power line detecting sensor and the jump line detecting sensor; A failure display control unit for outputting an information display control command when the power failure recovery due date is calculated by calculating a supervisory signal of the power line sensor and the jump line sensor and data on the time required for the recovery of the fault in the memory unit, A motor driving unit for sending a driving signal to the motor in accordance with a motor control command of the fault display control unit; and a control unit for controlling the motor driving unit to drive the left and right liquid crystal panels in accordance with the fault section display control command and the power- Fault display control means including a fault display driver for sending out a drive signal for the fault; And left and right bypass cut-off lines connected to the unit distribution lines located on the left and right sides of the electric pole, extending along the left and right sides of the outer periphery of the pole and connected to each other at lower ends thereof, A bypass underground line which is located between the left bypass cut-off line of the electric pole and the lower end of the right bypass cut-off line located on the right side and connected to the lower end of the right bypass cut-off line where the right end is disposed on the right side, A bottom line protection pipe embedded in the ground between the lower end of the electric pole and protecting the bypass underground line, and a lower end of the bypass lower line, And a power line sensor connected to the power line sensor, Depending on the detected signal of the line provides a fault section of the monitoring device to the distribution line, characterized by configured to include the bypass means comprising a bypass control means for controlling the left and right shutter.

According to the fault section line monitoring apparatus for a power distribution line according to the present invention, fault monitoring means, fault display means, and bypass means are provided to detect whether a unit distribution line and a jump line between a pole and a pole are faulty, And the failure situation including the fault area information and the information on the scheduled date of the power failure recovery can be displayed on the electric pole so that the field patrolman can see the fault situation at the sight in the field, It is possible to cope with a power failure and to provide convenience of living. Even if a fault occurs in a system for transmitting a fault signal and a fault signal can not be sent out, even if a patrol of a power company or a nearby customer To the management center so that the management center can quickly respond to the breakdown. In case of failure of each unit power distribution line, the unit distribution line located on both sides of the unit distribution line is directly connected to minimize the power outage by excluding power outage for the customer connected to the unit distribution line except for the customer connected to the unit distribution line where the failure occurs .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram of a fault line monitoring apparatus for a distribution line according to the present invention; FIG.
1 is a perspective view showing a normal power distribution state,
2 is a perspective view showing a fault occurrence state,
3 is an exploded perspective view of the failure monitoring means,
4 is an exploded perspective view of the fixed display means,
5 is an exploded perspective view showing a state in which the protective pipe of the bypass means is removed,
6 is an exploded perspective view showing a state in which a protective pipe of the bypass means is installed,
7 is an exploded perspective view of the switch,
8 is an enlarged front view of the failure display means showing a normal power distribution state,
9 to 11 are enlarged front views of a failure display means showing a failure occurrence state,
12 is an enlarged longitudinal sectional view of the switch showing a normal wiring state,
Fig. 13 is an enlarged longitudinal sectional view of the breaker showing the fault occurrence state,
14 is a functional block diagram of the failure monitoring means, the failure display control means and the bypass control means.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a fault section line monitoring apparatus for a distribution line according to the present invention will be described in detail with reference to the preferred embodiments illustrated in the accompanying drawings.

1 to 14 show a preferred embodiment of a fault section line monitoring apparatus for a distribution line according to the present invention.

In the following description, bolt fastening holes, bolts and nuts through which bolts are simply inserted and bolts are shown in some drawings, but the reference numerals and explanations thereof will be omitted.

As shown in FIG. 1 to FIG. 3, in the distribution line monitoring apparatus for a distribution line according to the present embodiment, in the distribution line to which the fault line monitoring apparatus for the distribution line according to the present invention is applied, (20) fixed to the electric pole (10), a unit power distribution line (40) supported in an insulated state via a suspending insulator (50) to the solid wire (20) And a jump line (60) connecting the unit distribution line (40).

A wrought iron fastener (30) is used to fix the wrought iron (20) to the electric pole (10). The wrought iron fastener 30 is composed of a pair of half bands surrounding the outer circumferential surface of the electric pole 10, a flat iron coupled to the middle part of the pair of half bands, and a bolt and a nut for fastening the pair of half bands Since this is used for fixing the bare iron 20 to the electric pole 10, a detailed description thereof will be omitted.

The fault line monitoring apparatus for a distribution line according to the present invention includes a fault detecting means 100 for detecting a fault of the unit distribution line 40, as shown in FIG. 1 to FIG. A failure display means (200) for displaying a failure status of the unit distribution line (40); And bypass means (400) for bypassing faulty unit distribution lines (40) when the unit distribution line (40) fails and bypassing the faulty unit distribution lines (40).

The failure monitoring means 100 includes a sensing sensor 110, a memory 120, a monitoring and controlling unit 130, a communication unit 140, and a remote monitoring server 150.

The detection sensor unit 110 includes a power line sensor 111 installed in the unit power distribution line 40 and a jump line detection sensor 112 installed in the jump line 60.

The sensing sensors 111 and 112 may use a current sensing sensor that senses a current flowing through the unit power distribution line 40 and the jump line 60.

The memory unit 120 stores a pole number, which is a unique number assigned to each pole 10, and failure data.

The failure data is stored for each of the power line detection sensor 111 and the jump line detection sensor 112 for detecting the failure of the unit power distribution line 40 and the jump line 60.

The supervisory control unit 130 transmits a polling number and a fault data storage command to the memory unit 120 in response to a detection signal of the sensing sensor unit 110 and transmits a polling number and a fault data transmission command to the communication unit 140 .

The communication unit 140 transmits the polling number and the fault data to the remote monitoring server 150 according to the transmission command of the monitoring control unit 130. The communication unit 140 includes an antenna 141 provided outside the first control box 160 to be described later.

The remote monitoring server 150 receives the polling number and the fault data and confirms the fault condition. In addition, the remote monitoring server 150 can send out the fault number to the repair person for the fault repair and recover it.

The memory unit 120, the monitoring control unit 130 and the communication unit 140 constituting the failure monitoring means 100 are installed on one circuit board 170 and the first control box 160 on the electric pole 10 by installing the circuit board 170 on the electric pole.

A charging battery 180 for supplying a message to the memory unit 120, the monitoring control unit 130 and the communication unit 140 is built in the first control box 160, (190) can be installed.

The charging circuit 190 is configured to convert a commercial current supplied from the unit power distribution line 40 into a charging current that can be charged into the charging battery 180.

The first control box 160 includes a first control box body 161 and a first control box door 162 rotatably connected to the first control box body 161.

The first control box body 161 and the first control box door 162 are rotatably connected to each other by a hinge 163 at one side and the lock piece 164 is locked at the other side by a lock 165. [ Respectively.

The hinge 163 and the locking piece 164 may be fixed to the first control box body 161 and the first control box door 162 by welding or screws.

An antenna 141 of the communication unit 140 is installed on the upper surface of the first control box body 161.

The first control box main body 161 includes a bolt B12 and a nut N12 on a flat plate 167 coupled to one side of a band 166 fixed to the electric pole 10 with bolts B11 and N11, As shown in Fig.

The fixed band 166 and the flat iron 167 are generally the same as the means for fixing the heavy iron to the electric pole 10, and a detailed description thereof will be omitted.

The failure display means 200 includes a mount 210 fixed to the solid iron 20, a motor 220 vertically mounted on the upper end of the mount 210 and facing the motor shaft 221 downward, Left and right sliders 230 and 240 that are slidable in the left and right directions on the mount 210 and are overlapped with each other in the forward and backward directions and pinion gears 230 and 240 that are positioned between the upper ends of the left and right sliders 230 and 240, A left rack 260 coupled to the left slider 230 and meshed with the pinion 250 at the front side and a left rack 260 coupled to the right slider 240 and coupled to the pinion 250 at the rear side, A left liquid crystal panel 280 attached to the front surface of the left slider 230, a right liquid crystal panel 290 attached to the front surface of the right slider 240, And the failure display control means 300 for controlling the left and right liquid crystal panels 280 and 290 It is configured to.

The mount 210 includes a vertical plate 211 vertically installed at one end of the wrought iron 20 and a vertical plate 211 horizontally extending from the upper end of the vertical plate 211 to be fixed to the wrought iron 20 A lower horizontal portion 214 formed at a lower end of the upper horizontal plate 213 and a lower horizontal portion 214 formed at a lower end of the upper horizontal portion 213 A lower vertical part 216 bent upward from the front end of the lower horizontal part 214 and a front side protrusion 217 formed on the upper surface of the lower side horizontal plate 214, And a rear side guide protrusion 218.

The vertical plate 211 is configured to guide the rear portion of the right slider 240.

The fixing part 212 is fixed by a bolt B21 which is seated on the upper surface of one end of the wrought iron 20 and penetrates the horizontal part 211 and the wrought iron 20 up and down and a nut N21 which is fastened thereto .

The upper horizontal part 213, the lower horizontal part 214, the upper vertical part 215 and the lower vertical part 216 are disposed on the right side slider 240, the left liquid crystal panel 280, Thereby preventing the liquid crystal panel 290 from deviating vertically and forward.

The motor 220 is vertically mounted on the upper surface of the upper horizontal portion 213 of the mount 210. The motor shaft 221 penetrates the upper horizontal portion 213 and is disposed on the rear surface of the left slider 230, And extends between the front surface of the slider 240.

The left slider 230 is slidably installed in a state of being separated from the front surface of the vertical plate 211. The right slider 240 slides between the front surface of the vertical plate 211 and the rear surface of the left slider 230, Lt; / RTI >

A space 231 for inserting the left liquid crystal panel 280 is formed on a front surface of the left slider 230 and a mounting space 241 for inserting the right liquid crystal panel 290 is formed on a front surface of the right slider 240. [ Is formed.

A guide groove 232 for inserting the front side guide protrusion 217 is formed on a lower surface of the left slider 230 and a guide groove 232 for inserting the rear side guide protrusion 218 is formed on a lower surface of the right side slider 240. [ (242) are formed.

A left opening and closing plate 233 for opening and closing a left opening between the vertical plate 211 of the mount 210 and the upper and lower horizontal portions 213 and 214 is provided at the left end of the left slider 230, A right side opening and closing plate 243 for opening and closing the right opening between the vertical plate 211 of the mount 210 and the upper and lower horizontal portions 213 and 214 is provided at the right end of the right slider 240.

The left opening / closing plate 233 and the right opening / closing plate 243 may be integrally formed with the left slider 230 and the right slider 240.

The pinion 250 is fixed to the motor shaft 221 by a common shaft and gear coupling method.

The left rack 260 is coupled to the upper rear surface of the left slider 230 and the right rack 270 is coupled to the upper front surface of the right slider 240.

The left rack 260 and the right rack 270 are connected to the left and right racks 260 and 270 by screws (not shown) passing through the left slider 230 and the upper ends of the right slider 240, And can be coupled to the left slider 230 and the right slider 240 by fastening them to screw fasteners (not shown).

The left liquid crystal panel 280 and the right liquid crystal panel 290 may be fixed to the left slider 230 and the right slider 240 by a screw (not shown).

The failure display control means 300 includes a memory unit 320 for storing failure data corresponding to the detection signals of the power distribution line sensor 111 and the jump line detection sensor 112 and a failure display control unit 330, 340 and a failure display driver 350. [

The memory unit 320 stores the failure data for each of the power line detection sensor 111 and the jump line detection sensor 112 for detecting the failure of the unit power distribution line 40 and the jump line 60.

In addition, the memory unit 320 stores data on the time required for the repair work for each failed part. The time required for the fault recovery operation is data on the time required for the operation to recover the fault when a fault occurs for each of the unit distribution line 40 and the jump line 60.

The failure recovery work time data is data on a period of time required for an operation according to a predetermined normal manual.

The left liquid crystal panel 280 and the right liquid crystal panel 290 may indicate whether the unit distribution line 40 and the jump line 430 are faulty,

The failure display control unit 330 may receive a failure data storage command for the memory unit 320 and a motor control command for the motor 220 and a command for controlling the left liquid crystal panel 280 according to a sensing signal of the sensing sensor unit 110. [ And the right liquid crystal panel 290 in accordance with the control signal.

The motor driving unit 340 is configured to send a motor driving signal to the motor 220 according to a motor control command of the failure display control unit 330.

The failure display driver 350 is configured to transmit a failure display driving signal to the left liquid crystal panel 280 and the right liquid crystal panel 290 according to a failure display control command of the failure display controller 330. [

The memory part 320, the failure display control part 330, the motor driving part 340 and the failure display driving part 350 constituting the failure display control part 300 are provided on one circuit board 370, It is possible to mount the circuit board 370 in the bare metal 20 by providing the circuit board 370 in the second control box 360 formed in an open box shape and fixed to the rear surface of the vertical plate 211 of the mount 210.

A failure display control unit 330, a motor driving unit 340 and a failure display driving unit 350 and a left liquid crystal panel 280 and a right liquid crystal panel 290 are disposed in the second control box 360. [ And a charging circuit 390 may be installed in the circuit board 370. The charging circuit 390 may be a battery charger.

The charging circuit 390 is configured to convert a commercial current supplied from the unit power distribution line 40 into a charging current capable of charging the charging battery 380. [

Here, the power source required for the failure monitoring means 100 and the power source required for the failure display means 200 and the failure display control means 300 can be composed of one rechargeable battery. However, the failure monitoring means 100, It is preferable that the controller 200 and the failure display control means 300 independently configure the remaining components except the detection sensor unit 110.

The electrical connection between the components constituting the failure monitoring means 100 and the failure display means 200 and the failure display control means 300 will not be shown and described.

Particularly, the left liquid crystal panel 280 and the right liquid crystal panel 290 can be connected to the failure display control means 300 by using a flexible printed circuit board (FPB).

The bypass means 400 is connected to the unit power distribution lines 40 located on the left and right sides of the electric pole 10 with respect to the electric pole 10 and extends along the left and right sides of the outer periphery of the electric pole 10, Down cut lines 411 and 412 buried in the ground between the electric pole 10 and the left side bypass cut line 411 of the electric pole 10 positioned on the left side and the right side cut line 411 of the electric pole 10 positioned on the right side, A bypass underground line 413 located between the lower ends of the path down line 412 and connected to the lower ends of the right bypass down line 412 of the pole 10 disposed at the right side on the right side, The bypass line 413 is embedded in the ground between the lower end of the electric pole 10 and the lower line protection pipes 420 and 430 which are fixed to the left and right sides of the outer circumference of the electric pole 10 to protect the left and right bypass cut- (440) for protecting the left bypass line (411) And a control unit for controlling the left and right switches 450 according to detection signals of the power line detecting sensor 111 and the jump line detecting sensor 112. The switch 450 is provided between the left end of the bypass line 413 and the left end of the bypass line 413, And a control means (490).

The left and right bypass lowering lines 411 and 412 can be connected to the unit power distribution line 40 through a connection port different from the connection port 70 connecting the unit power distribution line 40 and the jump line 60. However, Can be connected to the unit power distribution line (40) through the connection port (70).

The cut-off line protection pipes 420 and 430 are formed of synthetic resin pipes made of an insulating material and fixed to the electric pole 10 by a protective pipe fastener 421.

The protective pipe fixture 421 includes a pair of fixing bands 422 and 432 formed integrally with protective pipe supporting rings 423 and 433 to which the right and left down pipe protection pipes 420 and 430 are inserted and supported in the middle portion, And a tightening bolt B31 passing through both ends of the pair of fixing bands 422 and 432 and a tightening nut N31 fastened thereto.

The underwater protection pipe 440 is formed of a synthetic resin pipe made of an insulating material, and buried in the ground in the same manner as a conventional underground buried pipe.

The switch 450 is formed between the lower end of the left bypass line 411 of the electric pole 10 located on the left side and the left end of the bypass underground line 413 and is formed in the shape of a box having an open top, A switch housing main body 461 in which the lower end of the left bypass cut line 411 of the electric pole 10 located on the left side passes horizontally and the left end of the bypass undercut line 413 horizontally passes through the right wall, A switch housing housing 460 having an opening and closing housing cover 462 for covering the top opening of the switch housing main body 461 and a switch housing housing 460 installed horizontally in the left and right direction inside the switch housing housing body 461, A connecting member 470 connecting the lower end of the left bypass cut line 411 of the electric pole 10 located in the main body 10 to the bypass underground line 413 and a connector 470 mounted inside the switchgear housing main body 461, The solenoid 48 0).

The lower end of the left bypass cut line 411 is inserted into the inside of the left side wall of the switch housing main body 461 in a state in which the insulation coating at the lower end is peeled off and the conductor portion is exposed, The insulation cover is peeled off and the conductor portion is exposed through the right side wall of the switch housing main body 461 and inserted into the inside.

The switch housing main body 461 and the switch housing cover 462 have flanges extended to the upper edges of the switch housing main body 461 and bolts B41 passing through the switch housing cover 462, N41).

The connector 470 includes a conductor sleeve 471 electrically connected to the lower conductor portion of the left bypass line 411 and the left conductor portion of the bypass line 413, And an insulator 472 surrounding the outer circumferential surface.

In the illustrated example, two unit power distribution lines 40 are provided and two left and right bypass reduction lines 411 and 412 connected to the unit power distribution lines 40 are provided. In this case, the conductor sleeves 471 And the insulator 473 surrounds the two conductor sleeves 471. The conductor sleeve 471 is provided corresponding to the number of the unit power distribution lines 40. [

A tapered portion 472 is formed at both ends of the inner circumferential surface of the conductive sleeve 471 so as to extend outwardly so that the lower end of the left bypass cut line 411 and the left end of the bypass undercut line 412 are inserted smoothly. Is formed.

The insulator 473 may be formed of an insulating synthetic resin. The conductor sleeve 471 may be insert molded in the process of forming the insulator 473.

The insulator 473 includes a cylindrical portion 474 surrounding the conductor sleeve 471 and a connecting portion 475 integrally connecting the cylindrical body 474.

The solenoid 480 has a working rod 481 whose tip is coupled to the insulator 473. The solenoid 480 preferably uses a solenoid in which the operating rod 481 is retracted when power is turned off and the operating rod 481 is advanced when power is applied.

The insulator 473 and the operating rod 481 are connected to each other through a connector 476.

The connector 476 includes an engaging portion 477 coupled to the operating rod 481 and a screw rod 478 integrally formed with the engaging portion 477.

The operating rod 481 and the engaging portion 477 can be engaged by engaging the operating rod 481 with the engaging portion 477 and by fastening the nut N41 to the threaded portion formed on the outer peripheral surface of the operating rod 481 have.

The connecting portion 475 of the threaded rod 478 and the insulator 473 can be coupled by passing the threaded rod 478 through the connecting portion 475 and fastening the nut N42 to the threaded rod 478 .

The bypass control unit 490 includes a bypass control unit 491 for outputting a control command to the solenoid 480 according to a detection signal of the power line sensor 111 and the jump line sensor 112, And a solenoid driver 492 for transmitting a drive signal to the solenoid 480 according to a control command of the path controller 491. [

The bypass control unit 491 and the solenoid drive unit 492 constituting the bypass control means 490 can be installed on one circuit board and installed in the switch housing 460. [

In the illustrated example, the monitoring control unit 130, the failure display control unit 330, and the bypass control unit 491 are individually configured, but they may be integrated into one.

Hereinafter, the operation of the fault section line monitoring apparatus of the distribution line according to the present invention will be described.

The unit distribution line 40 and the jump line 60 are connected to the left and right sliders 230 and 240 and the left and right liquid crystal panels 280 and 280 in a state where the unit distribution line 40 and the jump line 60 are normally distributed in a state in which the distribution line monitoring apparatus (See FIG. 1), and the left and right liquid crystal panels 280 and 290 are installed in a state in which no information is displayed (see FIG. 8).

The failure detection signal is not output from the power line sensor 111 and the jump line sensor 112 while the power distribution through the unit power distribution line 400 and the jump line 60 is normally performed. The failure detection data is not transmitted to the remote monitoring server 150 through the memory unit 120, the monitoring control unit 130, and the communication unit 140. [

In addition, the failure detection control unit 330 of the failure display control means 300 does not receive a failure detection signal from the power distribution line sensor 111 and the jump line detection sensor 112. Therefore, failure display information through the memory unit 320 and the failure display control unit 330 is not displayed on the left and right liquid crystal panels 280 and 290. [

If the unit distribution line 40 and the jump line 60 are exaggerated due to weather or sunlight as time elapses after the installation of the distribution line to which the fault line monitoring apparatus for the distribution line according to the present invention is applied, The monitoring control unit 130 receives the failure detection signal from the power line detection sensor 111 and the jump line detection sensor 112 and outputs the failure detection signal to the monitoring control unit 130. [ Outputs a command to store the prime number and the fault data in the memory unit 120 according to the detection signal of the communication unit 140 and outputs the prime number and the fault data to the communication unit 140. [

The communication unit 140 transmits the polling number and the fault data to the remote monitoring server 150 through the antenna 141 in response to the transmission order of the polling number and the fault data and the remote monitoring server 150 transmits the polling number and the fault data It is possible to check the fault situation by receiving the input and send it to the repair person for the fault recovery to recover it.

On the other hand, the failure display control unit 330 of the failure display control means 300 detects the failure of the failure display device 200 based on the failure detection signals of the power distribution line sensor 111 and the jump line detection sensor 112, And displays the fault display control command, the fault detection signal, and the power recovery time data stored in the memory 320 in accordance with the fault detection signal, and outputs the information display control command at the power failure recovery due date .

The motor driving unit 340 sends a unidirectional driving signal for unfolding the left and right sliders 230 and 240 to the motor 220 according to the unfolding control command of the failure display control unit 330, And the left slider 230 and the left liquid crystal panel 280 coupled to the pinion 250 and the left and right racks 260 and 270 fixed to the motor shaft 221 are moved leftward and rightward, The slider 240 and the right liquid crystal panel 290 are moved to the right so that the left and right sliders 230 and 240 and the left and right liquid crystal panels 280 and 290 are spread to the left and right ).

In accordance with the failure section display control command of the failure display control section 330, the failure display driving section 350 displays the failure section display information on the left and right liquid crystal panels 280 and 290 and displays the information on the power failure recovery scheduled date (See Figs. 9 to 11).

Here, the fault section display information is displayed differently from the start point and the end point of the fault section and the intermediate point between the start point and the end point, respectively.

For example, at the time of the failure section, "→" is displayed on the upper half of the left liquid crystal panel 280 and the right liquid crystal panel 290 as failure section display information, and the " 101 to 200 ", and the "recovery job completion scheduled on June 10, 2010" can be displayed as the information on the power recovery recovery due date on the lower half of the right liquid crystal panel 290 (see Fig.

"←" is displayed on the upper half of the left liquid crystal panel 280, "→" is displayed on the upper half of the right liquid crystal panel 290 as the failure section display information at the middle point of the failure section, Quot; June 10, 2017 " to be completed can be displayed on the lower half of the right liquid crystal panel 290 as information on the scheduled recovery date of the power failure (" Yuguro 201 to 300 " 10).

"←" is displayed on the upper half of the left liquid crystal panel 280 and the right liquid crystal panel 290 as the failure section display information at the end of the failure section and the "blackout period 301" is displayed at the lower half of the left liquid crystal panel 280, 400 ", and "recovery job completion scheduled on June 10th" can be displayed on the lower half of the right liquid crystal panel 290 as information on the power recovery recovery due date (see Fig.

When the action for the failure has been completed, the initial state can be restored by the control of the failure monitoring means 100 and the failure display control means 300 or by a manual operation.

As described above, according to the fault monitoring apparatus for a processing power distribution line of the present invention, when a failure occurs in one or more of the unit power distribution line 40 and the jump line 60, It is possible to send fault data to the remote monitoring server 150 so as to take measures, and at the same time, the fault display means 200 and the fault display control means 300 display the fault section display information and the information on the power failure recovery due date, It is possible to confirm the failure by the patrol and the customer, and in particular, which part of the unit distribution line 40 and the jump line 60 can be identified, so that quick and appropriate measures can be taken.

In the fault line monitoring apparatus for a distribution line according to the present invention, the bypass unit 400 bypasses the left and right unit distribution lines 40 based on a period in which the unit distribution line 40 and the jump line 60 have failed And normal distribution can be performed in other sections except for the fault occurrence section.

The bypass control unit 491 of the bypass control unit 490 does not input the failure monitoring signal of the power distribution line sensor 111 and the jump line detection sensor 112 so that the solenoid 480 The solenoid drive unit 492 outputs a retraction actuation drive signal to the solenoid 480. As a result,

At this time, the driving signal for retracting operation of the solenoid driving unit 492 is a driving signal for shutting off the power to the solenoid 480, and the solenoid 480 retracts by the self-contained spring when the power is shut off The operating rod 481 of the solenoid 480 is retracted.

The insulator 473 and the conductor sleeve 471 connected to the working rod 481 through the connecting port 476 are retracted and the lower end of the bypass cut- The left bypass cut line 411 and the bypass undercut line 413 and the right bypass cut line 412 are kept in a state of being blocked from being moved to the left end of the pass underground line 413 ).

Thus, normal distribution is achieved through the unit distribution line 40 and the jump line 60.

A unit distribution line 40 between the pole 10 located on the left side and the pole 10 positioned on the right side in the distribution line including two electric poles 10, three unit distribution lines 40 and two jump lines 60 The unit distribution line 40 located on the left side of the pole 10 located on the left side and the unit distribution line 40 located on the right side of the pole 10 located on the right side are not faulty The bypass control unit 491 of the bypass control unit 490 outputs a forward operation control command to the solenoid 480 in response to the detection signals of the power distribution line sensor 111 and the jump line detection sensor 112, The solenoid drive unit 492 sends a forward operation drive signal to the solenoid 480 in accordance with the forward operation control command of the path control unit 491 so that the operation rod 481 of the solenoid 480 advances.

The insulator 473 and the conductor sleeve 471 connected to the operating rod 481 through the connecting port 476 are moved forward by the operating rod 481 to move forward to the left side of the bypass underground wire 413, The conductor sleeve 471 is connected to the lower end of the left bypass cut line 411 and the left end of the bypass undercut line 413 (see FIG. 13).

Therefore, the unit distribution line 40, the left bypass down line 411, the conductor sleeve 471, the bypass underground line 413, and the electric pole 10 located on the left side of the electric pole 10 located on the left side, The right side bypass line 412 and the right side unit distribution line 40 of the electric pole 10 positioned on the right side.

As a result, power is not distributed through the unit distribution line 40 between the unit distribution line where the fixation has occurred, that is, between the pole 10 located on the left side and the pole 10 located on the right side. However, The left bypass bypass line 411, the connecter 470, the bypass underground line 413 and the right bypass cut line (right side) located on the right side of the electric pole 10 located on the right side of the unit distribution line 40, the left bypass down line 411, 412), and power distribution through the right unit distribution line 40 is performed.

Therefore, a power failure occurs in the customer connected to the unit power distribution line 40 where the fixing occurs, but the power supply is not generated in the customer connected to the other power distribution line 40, so that the power outage interval can be minimized.

On the other hand, in the distribution line made up of four unit distribution lines 40 and three jump lines 60 provided in the three electric poles 10, two electric lines 10 located between the electric pole 10 located at the left end and the electric pole 10 located at the right end, When a failure occurs in the unit distribution line 40 and the jump line 60,

The left side bypass power line 40, the left bypass down line 411, the two bypass underwires 413 and the right side of the right first pole 10 are connected by the operation principle as described above, The power is distributed through the bypass down line 412 and the right unit distribution line 40.

That is, power distribution through the unit power distribution line 40 excluding the unit power distribution line 40 in which the failure occurs can be normally performed, so that the power generation section can be minimized.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or essential characteristics thereof. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: Jeonju 20: Wanchul
40: Unit distribution line 60: Jump line
100: Failure monitoring means 110: Detection sensor unit
111: Distribution line sensor 112: Jump line sensor
120: memory unit 130: monitoring control unit
140: communication unit 150: remote monitoring server
160: first control box 170: circuit board
180: battery 190: charging circuit
200: Failure display means 210: Mount
220: motor 230: left slider
240: right slider 250: pinion
260: Left rack 270: Right rack
280: left liquid crystal panel 290: right liquid crystal panel
300: Failure display control means 320:
330: Fault display control unit 340: Motor drive unit
350: failure display driver 360: second control box
370: circuit board 380: rechargeable battery
390: Charging circuit 400: Bypass means
411: Left bypass cut line 412: Right bypass cut line
413: bypass underground line 420, 430: down line protection pipe
440: underground protection pipe 450: switchgear
460: Actuator housing 470: Connector
480: Solenoid 490: Bypass control means
491: Bypass control unit 492: Solenoid driving unit

Claims (1)

A plurality of unit power distribution lines 40 supported in an insulated state via a suspending insulator 50 to a wrought iron 20 fixed to a plurality of electric poles 10 and a jump line 60 connecting the unit power distribution lines 40 In a fault section line monitoring apparatus for a distribution line,
A sensing sensor unit 110 including a power line sensor 111 installed at the unit distribution line 40 and a jump line sensor 112 installed at the jump line 60; A memory unit 120 for storing a polynomial number and fault data which is a unique number assigned to the memory unit 120 and a memory unit 120 for storing a polling number and a fault data in response to a detection signal of the detection sensor unit 110 And a communication unit (140) for transmitting the telephone number and the failure data to the remote monitoring server (150) according to a transmission command of the monitoring control unit (130);
A motor 220 mounted vertically on the upper end of the mount 210 and facing the motor shaft 221 so as to be slidable in the left and right direction of the mount 210; A pinion 250 which is positioned between the upper ends of the left and right sliders 230 and 240 and is fixed to the motor shaft 221 and a left pinion 250 fixed to the left and right sliders 230 and 240, A left rack 260 coupled to the right slider 240 and engaged with the pinion 250 at the front side and a right rack 270 coupled to the right slider 240 and engaged with the pinion 250 at the rear side, A failure display means 200 including a left liquid crystal panel 280 attached to a front surface of the left slider 230 and a right liquid crystal panel 290 attached to a front surface of the right slider 240;
A memory unit 320 for storing fault data and fault recovery time data for each fault and a motor control unit for controlling the motor 220 for the motor 220 according to a detection signal of the power supply line sensor 111 and the jump line sensor 112. [ And a failure section display control command for the left and right liquid crystal panels 280 and 290 and a supervisory signal of the power distribution line sensor 111 and the jump line detection sensor 112, A failure display control unit 330 for computing a time required for recovery of the star-malfunctioning operation data and outputting an information display control command when a power failure is to be recovered, and a drive control unit 330 for driving the motor 220 according to a motor control command of the malfunction display control unit 330 A driving signal for the left and right liquid crystal panels 280 and 290 in accordance with a failure section display control command and an information display control command at a power failure recovery due date of the failure display control section 330; To send out Fault indication control means 300 including the failure display driving unit 350; And
Right and left bypass cut-off lines 411 and 412 which are connected to the unit power distribution lines 40 located on the left and right sides of the electric pole 10 and which are connected to each other along the left and right sides of the outer periphery of the pole 10, And the lower bypass line 411 of the right side bypass line 411 of the electric pole 10 located on the right side of the electric pole 10 embedded in the ground between the electric pole 10 and the left side of the electric pole 10, A bypass line 413 connected to the lower end of the right bypass line 412 of the electric pole 10 located at the right end of the electric pole 10 and positioned on the left and right sides of the outer periphery of the electric pole 10, The underground line protection pipe 440 embedded in the ground between the lower end of the electric pole 10 and the bypass underground line 413 to protect the bypass underline 413, The lower end of the left bypass down line 411 and the bypass under line 413, And a bypass control means 490 for controlling the switch 450 in response to a detection signal from the power distribution line sensor 111 and the jump line detection sensor 112, And a bypass means (400) for monitoring the fault line of the distribution line.

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